Chapter 18 Two-Sample Problems BPS - 5th Ed. Chapter 18 1 Case Study Exercise and Pulse Rates A study performed to compare the mean resting pulse rate of adult subjects who regularly exercise to the mean resting pulse rate of those who do not regularly exercise. n mean std. dev. Exercisers 29 66 8.6 Nonexercisers 31 75 9.0 Is the mean resting pulse rate of adult subjects who regularly exercise different from the mean resting pulse rate of those who do not regularly exercise? BPS - 5th Ed. Chapter 18 2 Two-Sample Problems The goal of inference is to compare the responses to two treatments or to compare the characteristics of two populations. We have a separate sample from each treatment or each population. – Each sample is separate. The units are not matched, and the samples can be of differing sizes. BPS - 5th Ed. Chapter 18 3 Conditions for Comparing Two Means We have two independent SRSs, from two distinct populations – that is, one sample has no influence on the other-matching violates independence – we measure the same variable for both samples. Both populations are Normally distributed – the means and standard deviations of the populations are unknown – in practice, it is enough that the distributions have similar shapes and that the data have no strong outliers. BPS - 5th Ed. Chapter 18 4 Two-Sample t Procedures In order to perform inference on the difference of two means (μ1 – μ2), we’ll need the standard deviation of the observed difference x1 − x2 : 2 σ1 n1 BPS - 5th Ed. + 2 σ2 n2 Chapter 18 5 Two-Sample t Procedures Problem: We don’t know the population standard deviations σ1 and σ2. Estimate them with s1 and s2. The result is called the standard error, or estimated standard deviation, of the difference in the sample means. Solution: SE = BPS - 5th Ed. 2 s1 n1 + Chapter 18 2 s2 n2 6 Two-Sample t Confidence Interval an SRS of size n1 form a Normal population with unknown mean μ1, and draw an independent SRS of size n2 form another Normal population with unknown mean μ2. A confidence interval for μ1 – μ2 is: Draw (x1 − x2 ) ± t ∗ 2 s1 n1 + 2 s2 n2 – here t* is the critical value for confidence level C for the t density curve. The degrees of freedom are equal to the smaller of n1 – 1 and n2 – 1. BPS - 5th Ed. Chapter 18 7 Case Study Exercise and Pulse Rates Find a 95% confidence interval for the difference in population means (nonexercisers minus exercisers). 2 2 2 (8.6)2 s s ∗ (9.0) 1 x1 − x 2 ± t + 2 = 75 − 66 ± 2.048 + n1 n2 31 29 = 9 ± 4.65 = 4.35 to 13.65 “We are 95% confident that the difference in mean resting pulse rates (nonexercisers minus exercisers) is between 4.35 and 13.65 beats per minute.” BPS - 5th Ed. Chapter 18 8 Two-Sample t Significance Tests Draw an SRS of size n1 form a Normal population with unknown mean μ1, and draw an independent SRS of size n2 form another Normal population with unknown mean μ2. To test the hypothesis H0: μ1 = μ2, the test statistic is: t = ( x1 − x 2 ) − ( μ1 − μ 2 ) 2 s1 n1 + 2 s2 = n2 x1 − x 2 2 s1 n1 + 2 s2 n2 Use P-values for the t density curve. The degrees of freedom are equal to the smaller of n1 – 1 and n2 – 1. BPS - 5th Ed. Chapter 18 9 P-value for Testing Two Means Ha: Ha: Ha: μ1 > μ2 P-value is the probability of getting a value as large or larger than the observed test statistic (t) value. μ1 < μ2 P-value is the probability of getting a value as small or smaller than the observed test statistic (t) value. μ1 ≠ μ2 P-value is two times the probability of getting a value as large or larger than the absolute value of the observed test statistic (t) value. BPS - 5th Ed. Chapter 18 10 Case Study Exercise and Pulse Rates Is the mean resting pulse rate of adult subjects who regularly exercise different from the mean resting pulse rate of those who do not regularly exercise? Null: The mean resting pulse rate of adult subjects who regularly exercise is the same as the mean resting pulse rate of those who do not regularly exercise? [H0: μ1 = μ2] Alt: The mean resting pulse rate of adult subjects who regularly exercise is different from the mean resting pulse rate of those who do not regularly exercise? [Ha : μ1 ≠ μ2] Degrees of freedom = 28 (smaller of 31 – 1 and 29 – 1). BPS - 5th Ed. Chapter 18 11 Case Study 1. Hypotheses: 2. Test Statistic: t = H0: μ1 = μ2 x1 − x 2 2 s1 3. n1 + 2 Ha: μ1 ≠ μ2 75 − 66 = s2 (9.0) n2 31 2 + ≈ 3.961 (8.6) 2 29 P-value: P-value = 2P(T > 3.961) = 0.000207 (using a computer) P-value is smaller than 2(0.0005) = 0.0010 since t = 3.961 is greater than t* = 3.674 (upper tail area = 0.0005) (Table C) 4. Conclusion: Since the P-value is smaller than α = 0.001, there is very strong evidence that the mean resting pulse rates are different for the two populations (nonexercisers and exercisers). BPS - 5th Ed. Chapter 18 12 Robustness of t Procedures The two-sample t procedures are more robust than the one-sample t methods, particularly when the distributions are not symmetric. When the two populations have similar distribution shapes, the probability values from the t table are quite accurate, even when the sample sizes are as small as n1 = n2 = 5. When the two populations have different distribution shapes, larger samples are needed. In planning a two-sample study, it is best to choose equal sample sizes. In this case, the probability values are most accurate. BPS - 5th Ed. Chapter 18 13 Using the t Procedures Except in the case of small samples, the assumption that each sample is an independent SRS from the population of interest is more important than the assumption that the two population distributions are Normal. Small sample sizes (n1 + n2 < 15): Use t procedures if each data set appears close to Normal (symmetric, single peak, no outliers). If a data set is skewed or if outliers are present, do not use t. Medium sample sizes (n1 + n2 ≥ 15): The t procedures can be used except in the presence of outliers or strong skewness in a data set. Large samples: The t procedures can be used even for clearly skewed distributions when the sample sizes are large, roughly n1 + n2 ≥ 40. BPS - 5th Ed. Chapter 18 14